Honeycomb structure

ABSTRACT

A honeycomb structure having multiple honeycomb units united through a seal material layer, wherein each honeycomb unit has multiple through holes arranged side by side in a longitudinal direction and separated from each other by the wall surfaces of the through holes, is disclosed. The honeycomb units include at least: ceramic particles; and at least one of inorganic fibers and whiskers. At least one of the honeycomb units has a cross section perpendicular to a longitudinal direction thereof, the cross section having an area greater than or equal to about 5 cm 2  and less than or equal to about 50 cm 2 . The seal material layer has a thermal conductivity of about 0.1 W/m·K to about 5 W/m·K.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to a honeycomb structure.

2. Description of the Related Art

Conventionally, a common honeycomb catalyst used for conversion of automotive exhaust gas is manufactured by having a high specific surface area material such as activated alumina and catalyst metal such as platinum carried on the surface of a monolithic cordierite-based honeycomb structure having a low thermal expansion characteristic. Further, alkaline earth metal such as Ba is carried as a NO_(x) occlusion agent for processing NO_(x) in an oxygen-excess atmosphere such as a lean-burn engine or a diesel engine. In order to achieve a further improvement in conversion performance, it is necessary to increase the probability of contact of exhaust gas and the catalyst noble metal and the NO_(x) occlusion agent. This requires the carrier to have a higher specific surface area and the particles of the noble metal to be reduced in size and highly dispersed. However, a mere increase in the carried amount of a high specific surface area material such as activated alumina only results in an increase in the thickness of the alumina layer, thus causing a problem in that the probability of contact is not increased or that pressure loss is too high. Accordingly, some modifications have been made on cell shape, cell density, and wall thickness (for example, see JP-A 10-263416). On the other hand, as a honeycomb structure formed of a high specific surface area material, a honeycomb structure formed by extrusion molding using a composition including inorganic fibers and an inorganic binder is known (for example, see JP-A 5-213681). Further, a honeycomb structure formed by joining honeycomb units through an adhesion layer in order to increase the size of such a honeycomb structure is known (for example, see DE 4341159 A1).

The contents of JP-A 10-263416, JP-A 5-213681, and DE 4341159 A1 are incorporated herein by reference in their entirety.

SUMMARY OF THE INVENTION

According to one aspect of the present invention, provided is a honeycomb structure having a plurality of honeycomb units united through a seal material layer, the honeycomb units each having a plurality of through holes arranged side by side in a longitudinal direction and separated from each other by wall surfaces of the through holes, wherein the honeycomb units include at least ceramic particles and inorganic fibers and/or whiskers, at least one of the honeycomb units has a cross section perpendicular to a longitudinal direction thereof, the cross section having an area greater than or equal to about 5 cm² and less than or equal to about 50 cm², and the seal material layer has a thermal conductivity of about 0.1 W/m·K to about 5 W/m·K.

Thus, according to one embodiment of the present invention, a honeycomb structure that is capable of achieving high dispersion of a catalyst component and increasing strength against thermal shock and vibration, loses less heat, and has excellent thermal uniformity may be provided.

BRIEF DESCRIPTION OF THE DRAWINGS

Other objects, features and advantages of the present invention will become more apparent from the following detailed description when read in conjunction with the accompanying drawings, in which:

FIG. 1A is a conceptual diagram showing a honeycomb structure according to an embodiment of the present invention;

FIG. 1B is a conceptual diagram showing a honeycomb unit according to the embodiment of the present invention;

FIG. 2 is an SEM photograph of the wall surface of the honeycomb unit according to the embodiment of the present invention;

FIG. 3A is a diagram for illustrating experimental examples in which the honeycomb units were joined according to the embodiment of the present invention;

FIG. 3B is a diagram for illustrating other experimental examples in which the honeycomb units were joined according to the embodiment of the present invention;

FIG. 3C is a diagram for illustrating other experimental examples in which the honeycomb units were joined according to the embodiment of the present invention;

FIG. 3D is a diagram for illustrating other experimental examples in which the honeycomb units were joined according to the embodiment of the present invention;

FIG. 4A is a diagram for illustrating other experimental examples in which the honeycomb units were joined according to the embodiment of the present invention;

FIG. 4B is a diagram for illustrating other experimental examples in which the honeycomb units were joined according to the embodiment of the present invention;

FIG. 4C is a diagram for illustrating other experimental examples of the honeycomb unit according to the embodiment of the present invention;

FIG. 5A is a front view of a vibration apparatus according to the embodiment of the present invention;

FIG. 5B is a side view of the vibration apparatus according to the embodiment of the present invention;

FIG. 6 is a diagram for illustrating a pressure loss measuring apparatus according to the embodiment of the present invention;

FIG. 7 is a graph showing the relationship between the cross-sectional area of the honeycomb unit and each of weight reduction rate and pressure loss according to the embodiment of the present invention;

FIG. 8 is a graph showing the relationship between unit area ratio and each of weight reduction rate and pressure loss according to the embodiment of the present invention; and

FIG. 9 is a graph showing the relationship between the aspect ratio of silica-alumina fibers and weight reduction rate according to the embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

Next, a description is given, with reference to the accompanying drawings, of an embodiment of the present invention.

FIG. 1A is a conceptual diagram of a honeycomb structure 10 according to the embodiment of the present invention. Referring to FIG. 1A, the honeycomb structure 10 according to this embodiment is formed by uniting multiple honeycomb units 11 through a seal material layer 14. Each honeycomb unit 11 has multiple through holes 12 arranged side by side in a longitudinal direction, being separated by through hole wall surfaces. Each honeycomb unit 11 includes at least ceramic particles and inorganic fibers and/or whiskers. The area of a cross section of the honeycomb unit 11 perpendicular to a longitudinal direction thereof is greater than or equal to about 5 cm² and less than or equal to about 50 cm². The thermal conductivity of the seal material layer 14 is about 0.1 W/m·K to about 5 W/m·K.

This honeycomb structure 10 has the multiple honeycomb units 11 joined through the seal material layer 14. Accordingly, it is possible to increase strength against thermal shock and vibration. It is inferred that this is because it is possible to reduce a difference in temperature in each honeycomb unit 11 even when there is a distribution of temperature in the honeycomb structure 10 because of a sudden change in temperature, or because it is possible to ease thermal shock and vibration with the seal material layer 14. Further, it is believed that also in the case of formation of cracks in one or more of the honeycomb units 11 due to thermal stress, the seal material layer 14 prevents the cracks from extending to the entire honeycomb structure 10 and serves as the frame of the honeycomb structure 10 to maintain the shape as a honeycomb structure, thereby preventing the honeycomb structure 10 from losing the ability to function as a catalyst carrier. With respect to the size of each honeycomb unit 11, if the area of a cross section of the honeycomb unit 11 perpendicular to its through holes 12 (hereinafter, simply referred to as “cross-sectional area”) is greater than or equal to about 5 cm², the cross-sectional area of the seal material layer 14 joining the multiple honeycomb units 11 decreases so as to be able to relatively increase the specific surface area carrying a catalyst and relatively reduce pressure loss. On the other hand, if the cross-sectional area of the honeycomb unit 11 is less than or equal to about 50 cm², the honeycomb unit 11 is not too large in size, and accordingly, can sufficiently control thermal stress generated therein. That is, with a cross-sectional area of about 5 cm² to about 50 cm², each honeycomb unit 11 is at a practicable level, having reduced pressure loss, sufficient strength against thermal stress, and high durability while maintaining large specific surface area. Therefore, according to this honeycomb structure 10, it is possible to cause a catalyst component to be highly dispersed, and to increase strength against thermal shock and vibration. If the honeycomb structure 10 includes multiple types of honeycomb units having different cross-sectional areas, the term “cross-sectional area” refers to the cross-sectional area of a honeycomb unit that is a basic unit of the honeycomb structure 10, and usually refers to the largest one of the cross-sectional areas of the honeycomb units.

Further, in this honeycomb structure 10, the thermal conductivity of the seal material layer 14 falls within the range of about 0.1 W/m·K to about 5 W/m·K, so that good thermal conductivity can be obtained. Accordingly, in the case of configuring an exhaust gas purification (conversion) device by combining the honeycomb structure 10 with a diesel particulate filter (DPF), the advantage can be obtained that heat loss is reduced at the position of the honeycomb structure 10 so that heat is conducted efficiently to the DPF for capturing particulates provided on the subsequent stage side, thus increasing the regeneration rate of the DPF. If the thermal conductivity of the seal material layer 14 is greater than or equal to about 0.1 W/m·K, the seal material layer 14 is less likely to serve as thermal resistance, so that the thermal conduction characteristic of the honeycomb structure 10 is less likely to be impaired. On the other hand, if the thermal conductivity of the seal material layer 14 is less than or equal to 5 W/m·K, the gas purification (conversion) characteristic and the thermal resistance of the honeycomb structure 10 are less likely to be impaired. Accordingly, preferably, the thermal conductivity of the seal material layer 14 is within the range of about 0.1 W/m·K to about 5 W/m·K. It is possible to control the thermal conductivity of the seal material layer 14 by changing the type, size, compounding ratio, etc., of ceramic particles, inorganic fibers, and an additive.

The ratio of the total of the cross-sectional areas of the honeycomb units 11 (the areas of cross sections of the honeycomb units 11 perpendicular to a longitudinal direction thereof) to the cross-sectional area of the honeycomb structure 10 (the area of a cross section of the honeycomb structure 10 perpendicular to a longitudinal direction thereof) is preferably greater than or equal to about 85%, and more preferably, greater than or equal to about 90%. If this ratio is greater than or equal to about 85%, the cross-sectional area of the seal material layer 14 decreases so as to increase the total cross-sectional area of the honeycomb units 11. Therefore, it is possible to relatively increase the specific surface area carrying a catalyst, and to relatively reduce pressure loss. When this ratio is greater than or equal to about 90%, it is possible to further reduce pressure loss.

The honeycomb structure 10 according to this embodiment may include a coating material layer 16 (FIG. 1A) coating the exterior axial surface (exterior cylindrical surface in the case of FIG. 1A) of the joint body of the honeycomb units 11, or the exterior surface of the joint body of the honeycomb units 11 which surface is along the axial directions of the joint body. This protects the exterior cylindrical surface of the honeycomb structure 10, so that its strength can be increased.

The honeycomb structure 10 into which the honeycomb units 11 are joined is not limited in shape in particular, and may have any shape and size. For example, the honeycomb structure 10 may also be shaped like a cylinder, a prism, or an elliptic cylinder.

In the honeycomb structure 10 of this embodiment, the aspect ratio of inorganic fibers and/or whiskers included in each honeycomb unit 11 is preferably about 2 to about 1000, more preferably, about 5 to about 800, and most preferably, about 10 to about 500. If the aspect ratio of inorganic fibers and/or whiskers is greater than or equal to about 2, it is possible to increase their contribution to an increase in the strength of the honeycomb structure. On the other hand, aspect ratios less than or equal to about 1000 are less likely to cause clogging of a die for extrusion molding at the time of molding, thus resulting in good moldability. Further, at the time of molding such as extrusion molding, the inorganic fibers and/or whiskers are less likely to break, and accordingly, are less likely to vary in length, thus increasing their contribution to an increase in the strength of the honeycomb structure 10. If the inorganic fibers and/or whiskers have their aspect ratios distributed, the aspect ratio of inorganic fibers and/or whiskers may be their average.

In the honeycomb structure 10 of this embodiment, the ceramic particles included in each honeycomb unit 11 are not limited in particular. The ceramic particles include one or more selected from, for example, silicon carbide, silicon nitride, alumina, silica, zirconia, titania, ceria, mullite, and zeolite. Of these, alumina is preferred.

In the honeycomb structure 10 of this embodiment, the inorganic fibers and/or whiskers included in each honeycomb unit 11 are not limited in particular. The inorganic fibers and/or whiskers include one or more selected from alumina, silica, silicon carbide, silica alumina, aluminum borate, glass, and potassium titanate.

The ceramic particles included in the honeycomb structure 10 are preferably about 30 wt % to about 97 wt %, more preferably about 30 wt % to about 90 wt %, still more preferably about 40 wt % to about 80 wt %, and most preferably about 50 wt % to about 75 wt % in amount. If the ceramic particles content is greater than or equal to about 30 wt %, the ceramic particles contributing to an increase in the specific surface area relatively increase in amount. This increases the specific surface area as a honeycomb structure so as to make it possible to carry a catalyst component with high dispersion easily. If the ceramic particles content is less than or equal to about 90 wt %, the inorganic fibers and/or whiskers contributing to an increase in strength relatively increase in amount, so that the strength of the honeycomb structure 10 is less likely to be reduced.

The inorganic fibers and/or whiskers included in the honeycomb structure 10 are preferably about 3 wt % to about 70 wt %, more preferably about 3 wt % to about 50 wt %, still more preferably about 5 wt % to about 40%, and most preferably about 8 wt % to about 30 wt % in amount. If the inorganic fibers and/or whiskers content is greater than or equal to about 3 wt %, the strength of the honeycomb structure 10 is less likely to be reduced. If the inorganic fibers and/or whiskers content is less than or equal to about 50 wt %, the ceramic particles contributing to an increase in the specific surface area relatively increase in amount. This increases the specific surface area as a honeycomb structure so as to make it possible to carry a catalyst component with high dispersion easily.

In the honeycomb structure 10 of this embodiment, each honeycomb unit 11 may also be manufactured with further inclusion of an inorganic binder. This makes it possible to obtain sufficient strength even when firing is performed on the honeycomb unit 11 at lower temperatures. The inorganic binder included in the honeycomb structure 10 is not limited in particular. The inorganic binder may be, for example, inorganic sol, a clay-based binder, etc. Of these, the inorganic sol includes one or more selected from, for example, alumina sol, silica sol, titania sol, and water glass. The clay-based binder includes one or more selected from, for example, clay, kaolin, montmonrillonite, and clays of a double-chain structure type (sepiolite and attapulgite). The inorganic binder included in the material of the honeycomb structure 10 is preferably less than or equal to about 50 wt %, more preferably about 5 wt % to about 50 wt %, still more preferably about 10 wt % to about 40 wt %, and most preferably about 15 wt % to about 35 wt % in amount as a solid content included in the honeycomb structure 10. If the inorganic binder content is less than or equal to about 50 wt % in amount, moldability is prevented from being degraded.

The shape of each honeycomb unit 11 is not limited in particular. Preferably, the honeycomb units 11 are shaped so as to facilitate joining of the honeycomb units 11. A section of the honeycomb unit 11 perpendicular to the through holes 12 (hereinafter, simply referred to as “cross section”) may be square, rectangular, hexagonal, or fan-shaped. FIG. 1B is a conceptual diagram of an example of the honeycomb units 11, which is a parallelepiped one having a square cross section. Referring to FIG. 1B, the honeycomb unit 11 includes the multiple through holes 12 extending from the front side to the rear side, and an exterior surface 13 having no openings of the through holes 12. The thickness of the wall between the through holes 12 is not limited in particular. The wall thickness is preferably about 0.05 mm to about 0.35 mm, more preferably about 0.10 mm to about 0.30 mm, and most preferably about 0.15 mm to about 0.25 mm. If the wall thickness is greater than or equal to about 0.05 mm, the strength of the honeycomb unit 11 is prevented from being reduced. On the other hand, if the wall thickness is less than or equal to about 0.35 mm, the area of contact with exhaust gas increases, so that the exhaust gas is likely to penetrate sufficiently deeply. As a result, a catalyst carried on the inside of the wall is likely to come into contact with the exhaust gas, so that it is possible to improve catalyst performance. Further, the number of through holes 12 per unit cross-sectional area is preferably about 15.5/cm² to about 186/cm² (about 100 cpsi to about 1200 cpsi), more preferably about 46.5/cm² to about 170.5/cm² (about 300 cpsi to about 1100 cpsi), and most preferably about 62.0/cm² to about 155/cm² (about 400 cpsi to about 1000 cpsi). If the number of through holes 12 is greater than or equal to about 15.5/cm², the area of the wall inside the honeycomb unit 11 which wall contacts exhaust gas increases. If the number of through holes 12 is less than or equal to about 186/cm², pressure loss is less likely to increase, and it is easy to manufacture the honeycomb unit 11.

The shape of the through holes 12 formed in the honeycomb unit 11 is not limited in particular. The through holes 12 may also have substantially triangular or hexagonal cross sections.

Each honeycomb unit 11 forming the honeycomb structure 10 may be of such size as to have a cross-sectional area of preferably about 5 cm² to about 50 cm², more preferably about 6 cm² to about 40 cm², and most preferably about 8 cm² to about 30 cm². If the cross-sectional area falls within the range of about 5 cm² to about 50 cm², it is possible to control the ratio of the seal material layer 14 to the honeycomb structure 10. This makes it possible to keep high the specific surface area per unit volume of the honeycomb structure 10, and accordingly, to have a catalyst component highly dispersed. This also makes it possible to maintain the shape as a honeycomb structure even if an external force such as thermal shock or vibration is applied. The cross-sectional area is preferably greater than or equal to about 5 cm² also because pressure loss is reduced. The specific surface area per unit volume can be given by Eq. (1) described below.

An object of the present invention may be to provide a honeycomb structure that is capable of achieving high dispersion of a catalyst component and increasing strength against thermal shock and vibration, loses less heat, and has excellent thermal uniformity.

According to one embodiment of the present invention, a carrier can have a higher specific surface area, and the particles of a catalyst metal can be reduced in size and can be more highly dispersed. That is, it is possible to increase the specific surface area of a high specific surface area material such as alumina at its initial stage. Accordingly, even if sintering of a high specific surface area material progresses because of thermal aging (use as a catalyst carrier), and with this, a catalyst metal such as platinum carried thereon coheres so as to increase in particle size, it is possible to maintain a high specific surface area. As a result, it is possible to increase the probability of contact of exhaust gas with a catalyst noble metal and a NO_(x) occlusion agent and thus to achieve a further improvement in conversion performance without carrying a large amount of noble metal such as platinum, which is very expensive and a limited valuable resource, as catalyst metal or increasing the size of a catalyst carrier itself. Further, since a catalyst carrier itself is not increased in size, it is suitable for installation in automobiles, which are limited in space for installation. Further, since it is possible to increase the specific surface area of the carrier without reducing the thickness of its partition walls, sufficient strength can be obtained. Further, a honeycomb structure has multiple honeycomb units joined through a seal material layer. This makes it possible to reduce a difference in temperature in each honeycomb unit even when there is a distribution of temperature in the honeycomb structure because of a sudden change in temperature. This also makes it possible to ease thermal shock and vibration with the seal material layer. Further, in the case of formation of cracks in one or more of the honeycomb units due to thermal stress, the seal material layer prevents the cracks from extending to the entire honeycomb structure and serves as the frame of the honeycomb structure to maintain the shape as a honeycomb structure. Accordingly, even if thermal stress due to a sudden change in temperature or external force such as great vibration is applied in the case of, for example, use for automobiles, the honeycomb structure is prevented from breaking easily, and can maintain the shape as a honeycomb structure and accordingly, function as a catalyst carrier. Further, the honeycomb structure has good thermal conductivity. Accordingly, in the case of forming an exhaust gas purification (conversion) device by combining the honeycomb structure and a DPF, heat loss is reduced at the position of the honeycomb structure so that heat is conducted efficiently to the DPF on the subsequent stage side. This leads to a higher particulate purification rate and a higher DPF regeneration rate.

Next, a description is given of a method of manufacturing the above-described honeycomb structure 10 of this embodiment. First, honeycomb unit molded bodies are made by extrusion molding using raw material paste including the above-described ceramic particles, inorganic fibers and/or whiskers, and inorganic binder as principal components. In addition to these, an organic binder, a dispersion medium, and a molding aid may be added appropriately to the raw material paste in accordance with moldability. The organic binder is not limited in particular. The organic binder includes one or more organic binders selected from, for instance, methylcellulose, carboxymethylcellulose, hydroxyethylcellulose, polyethylene glycol, phenolic resin, and epoxy resin. The mix proportion of the organic binder is preferably about 1 part to about 10 parts by weight to the total of 100 parts by weight of the ceramic particles, the inorganic fibers and/or whiskers, and the inorganic binder. The dispersion medium is not limited in particular, and may be, for example, water, an organic solvent (such as benzene), alcohol (such as methanol), etc. The molding aid is not limited in particular, and may be, for example, ethylene glycol, dextrin, a fatty acid, fatty acid soap, and polyalcohol.

The raw material paste is not limited in particular. It is preferable to mix and knead the raw material paste. For example, the raw material paste may be mixed using a mixer or attritor, and may be well kneaded with a kneader. The method of molding the raw material paste is not limited in particular. Preferably, the raw material paste is formed into a shape having through holes by, for example, extrusion molding or the like.

Next, it is preferable to dry the obtained molded bodies. The drier used for drying is not limited in particular, and may be a microwave drier, hot air drier, dielectric drier, reduced-pressure drier, vacuum drier, and freeze drier. Further, it is preferable to degrease the obtained molded bodies. The conditions for degreasing are not limited in particular, and are selected suitably in accordance with the organic matter included in the molded bodies. Preferably, the conditions are a heating temperature of approximately 400° C. and a heating time of approximately 2 hours. Further, it is preferable to subject the obtained molded bodies to firing. The condition for firing is not limited in particular, and is preferably at about 600° C. to about 1200° C., and more preferably at about 600° C. to about 1000° C. This is because sintering of the ceramic particles progresses sufficiently at firing temperatures higher than or equal to about 600° C., thus resulting in increased strength as a honeycomb structure, and because sintering of the ceramic particles does not progress excessively at firing temperatures lower than or equal to about 1200° C., thus preventing the specific surface area per unit volume from being reduced, so that a carried catalyst component can be dispersed highly enough. By way of these processes, the honeycomb units 11 each having the multiple through holes 12 can be obtained.

Next, the paste of a seal material to serve as the seal material layer 14 is applied on the obtained honeycomb units 11, and the honeycomb units 11 are successively joined. Thereafter, the honeycomb units 11 may be dried and solidified so as to be formed into a honeycomb unit joint body of a predetermined size. The seal material is not limited in particular. For example, a mixture of an inorganic binder and ceramic particles, a mixture of an inorganic binder and inorganic fibers, and a mixture of an inorganic binder, ceramic particles, and inorganic fibers may be used as the seal material. An organic binder may be added to these seal materials. The organic binder is not limited in particular, and includes one or more selected from, for example, polyvinyl alcohol, methylcellulose, ethylcellulose, and carboxymethylcellulose.

The seal material layer 14 joining the honeycomb units 11 is preferably about 0.3 mm to about 2 mm in thickness. If the seal material layer 14 is greater than or equal to about 0.3 mm in thickness, sufficient joining strength is likely to be obtained. Further, the seal material layer 14 is a part that does not function as a catalyst carrier. Accordingly, if the seal material layer 14 is less than or equal to about 2 mm in thickness, the specific surface area per unit volume of the honeycomb structure 10 is less likely to be reduced, thus making it easier to carry a catalyst component with sufficiently high dispersion. Further, if the seal material layer 14 is less than or equal to about 2 mm in thickness, pressure loss is prevented from increasing excessively. The number of honeycomb units 11 to be joined may be determined suitably in accordance with the size of the honeycomb structure 10 to be used as a honeycomb catalyst. Further, the joint body into which the honeycomb units 11 are joined with the seal material may also be cut and ground suitably in accordance with the shape and size of the honeycomb structure 10.

The coating material layer 16 may be formed by applying a coating material on the exterior cylindrical surface (side surface) of the joint body of the honeycomb units 11, and drying and solidifying the coating material. This makes it possible to increase strength by protecting the exterior cylindrical surface of the honeycomb structure 10. The coating material is not limited in particular, and may be either equal to or different from the seal material in material. Further, the coating material may be equal to or different from the seal material in compounding ratio. The thickness of the coating material layer 16 is not limited in particular, and is preferably about 0.1 mm to about 2 mm. With thicknesses greater than or equal to about 0.1 mm, the coating material layer 16 can sufficiently protect the exterior cylindrical surface of the honeycomb structure 10, thus preventing a decrease in its strength. If the coating material layer 16 is less than or equal to about 2 mm in thickness, the specific surface area per unit volume as a honeycomb structure does not decrease so that it is possible to carry a catalyst component with sufficiently high dispersion easily.

It is preferable to perform calcination after joining the multiple honeycomb units 11 with the seal material (or after the coating material layer 16 is formed in the case of providing the coating material layer 16). This is because if an organic binder is included in the seal material or the coating material, the organic material can be removed by degreasing. The conditions for calcination may be determined suitably in accordance with the type and amount of the included organic binder. Preferably, the calcination is performed for approximately 2 hours at approximately 700° C. Referring back to FIG. 1A, as an example honeycomb structure, the honeycomb structure 10 of this embodiment is formed so as to have a cylindrical shape by joining the multiple parallelepiped honeycomb units 11 each having a square cross section. The honeycomb structure 10 is formed by joining the honeycomb units 11 with the seal material layer 14, cutting the joined honeycomb units 11 into a cylindrical shape, and thereafter, coating the exterior cylindrical surface of the joint body of the honeycomb units 11 with the coating material layer 16. The unevenness of the exterior cylindrical surface of the joint body of the honeycomb units 11 due to the cutting or grinding is eliminated by filling the concave parts of the exterior cylindrical surface with the coating material layer 16. The concave parts of the exterior surface may not be filled with the coating material layer 16. Alternatively, the honeycomb units 11 may be molded so as to have fan-shaped and square cross sections, and joined into a predetermined honeycomb structure shape (a cylindrical shape in FIG. 1A), thereby omitting the cutting and grinding process.

The obtained honeycomb structure 10 is not limited to a particular use. It is preferable to use the obtained honeycomb structure 10 as a catalyst carrier for converting the exhaust gas of vehicles. In the case of using the honeycomb structure 10 as a catalyst carrier for converting the exhaust gas of a diesel engine, the honeycomb structure 10 is used with a diesel particulate filter (DPF) having a ceramic honeycomb structure of silicon carbide or the like and having the function of purifying the exhaust gas by filtering out and burning particulate matter (PM) therein. In this case, the positional relationship between the honeycomb structure 10 of this embodiment and the DPF is such that the honeycomb structure 10 of this embodiment may be provided either on the preceding stage side or on the subsequent stage side. In the case of providing the honeycomb structure 10 on the preceding stage side, it is possible to transfer heat generated in the honeycomb structure 10 to the DPF on the subsequent stage side effectively with reduced heat loss since the seal material layer 14 of the honeycomb structure 10 has a sufficiently high thermal conductivity. Accordingly, it is possible to cause a uniform rise in temperature at the time of regeneration of the DPF, thus improving the regeneration rate of the DPF. In the case of providing the honeycomb structure 10 on the subsequent stage side, the exhaust gas passes through the through holes 12 of the honeycomb structure 10 after the PM in the exhaust gas is filtered out by the DPF. Accordingly, clogging is less likely to occur in the honeycomb structure 10. Further, a gas component generated by incomplete combustion at the time of burning the PM in the DPF can also be processed using the honeycomb structure 10 of this embodiment. The honeycomb structure 10 may be used for the purpose described above with reference to the background of the present invention. In addition, the honeycomb structure 10 may also be applied to, but is not limited in particular to, use without carrying a catalyst component (for example, as an adsorbent adsorbing a gas component or a liquid component).

Further, the obtained honeycomb structure 10 may be made a honeycomb catalyst by having a catalyst component carried thereon. The catalyst component is not limited in particular, and may be noble metal, alkali metal, alkaline earth metal, oxide, etc. The noble metal includes one or more selected from, for example, platinum, palladium, and rhodium. The alkali metal includes one or more selected from, for example, potassium and sodium. Examples of the alkaline earth metal include a barium compound. Examples of the oxide include perovskite (such as La_(0.75)K_(0.25)MnO₃) and CeO₂. The obtained honeycomb catalyst is not limited to a particular use, and may be used as, for example, a so-called three-way catalyst or a NO_(x) occlusion catalyst for converting automobile exhaust gas. There is no particular limitation with respect to the carrying of a catalyst component. The catalyst component may be carried either after manufacturing the honeycomb structure 10 or at the stage of raw material ceramic particles. The method of carrying a catalyst component is not limited in particular, and may be, for example, impregnation.

EXAMPLES

A description is given below of the specific cases of manufacturing honeycomb structures under various conditions as experimental examples. The present invention is not limited to these experimental examples.

Example 1

First, 40 wt % of γ-alumina particles (2 μm in average particle size), 10 wt % of silica-alumina fibers (10 μm in average fiber diameter, 100 μm in average fiber length, and of an aspect ratio of 10), and 50 wt % of silica sol (of a solid concentration of 30 wt %) were mixed. Six parts by weight of methylcellulose as an organic binder was added, together with small amounts of a plasticizer and lubricant, to 100 parts by weight of the obtained mixture. The mixture was further mixed and kneaded, so that a mixture composition was obtained. Next, the mixture composition was subjected to extrusion molding by an extruder, so that crude molded bodies were obtained.

The crude molded bodies were sufficiently dried using a microwave drier and a hot air drier, and were degreased, being heated at 400° C. for 2 hours. Thereafter, the molded bodies were subjected to firing, being heated at 800° C. for 2 hours. As a result, the honeycomb units 11 each having a prism-like shape (34.3 mm×34.3 mm×150 mm), a cell density of 93/cm² (600 cpsi), a wall thickness of 0.2 mm, and a quadrangular (square) cell shape were obtained. FIG. 2 shows a scanning electron microscope (SEM) photograph of the wall surface of one of the honeycomb units 11. This shows that silica-alumina fibers are oriented along the extrusion direction of the raw material paste in this honeycomb unit 11.

Next, 29 wt % of γ-alumina particles (2 μm in average particle size), 7 wt % of silica-alumina fibers (10 μm in average fiber diameter and 100 μm in average fiber length), 34 wt % of silica sol (of a solid concentration of 30 wt %), 5 wt % of carboxymethylcellulose, and 25 wt % of water were mixed into heat-resisting seal material paste. The honeycomb units 11 were joined using this seal material paste. FIG. 3A shows a joint body into which the honeycomb units 11 are joined, viewed from a surface thereof on which the through holes 12 are formed (hereinafter referred to as “front surface”). This joint body was formed by joining and solidifying the honeycomb units 11 with the seal material paste being applied on the exterior surfaces 13 of the honeycomb units 11 so that the seal material layer 14 was 1 mm in thickness. The joint body was thus made, and the joint body was cut cylindrically using a diamond cutter so that the front surface of the joint body was substantially symmetric about a point. Further, the above-described seal material paste was applied on the exterior cylindrical surface on which no through holes were formed so as to be 0.5 mm in thickness, thereby coating the exterior cylindrical surface. Thereafter, the obtained structure was dried at 120° C., and the seal material layer 14 and the coating material layer 16 were degreased while heating the structure at 700° C. for 2 hours. As a result, the honeycomb structure 10 having a cylindrical shape (143.8 mm in diameter and 150 mm in length) was obtained. Table 1 shows a collection of data such as numerical values on the ceramic particle component, unit shape, unit cross-sectional area, unit area ratio (the ratio of the total cross-sectional area of the honeycomb units 11 to the cross-sectional area of the honeycomb structure 10, which applies hereinafter), and seal material layer area ratio (the ratio of the total cross-sectional area of the seal material layer 14 and the coating material layer 16 to the cross-sectional area of the honeycomb structure 10, which applies hereinafter) of this honeycomb structure 10.

TABLE 1 UNIT CROSS- UNIT AREA SEAL²⁾ MATERIAL UNIT SHAPE SECTIONAL AREA RATIO LAYER AREA RATIO SAMPLE¹⁾ CERAMIC PARTICLES cm cm² % % EXAMPLE 1 ALUMINA 3.43 SQUARE 11.8 93.5 6.5 EXAMPLE 2 ALUMINA 2.00 SQUARE 4.0 89.7 10.3 EXAMPLE 3 ALUMINA 2.24 SQUARE 5.0 90.2 9.8 EXAMPLE 4 ALUMINA 7.09 FAN 39.5 96.9 3.1 EXAMPLE 5 ALUMINA 7.10 SQUARE 50.0 95.5 4.5 EXAMPLE 6 ALUMINA 7.41 SQUARE 55.0 95.6 4.4 EXAMPLE 7 ALUMINA MONOLITHIC 162.0 100.0 0 EXAMPLE 8 TITANIA 3.43 SQUARE 11.8 93.5 6.5 EXAMPLE 9 TITANIA 2.00 SQUARE 4.0 89.7 10.3 EXAMPLE 10 TITANIA 2.24 SQUARE 5.0 90.2 9.8 EXAMPLE 11 TITANIA 7.09 FAN 39.5 96.9 3.1 EXAMPLE 12 TITANIA 7.10 SQUARE 50.0 95.5 4.5 EXAMPLE 13 TITANIA 7.41 SQUARE 55.0 95.6 4.4 EXAMPLE 14 TITANIA MONOLITHIC 162.0 100.0 0 EXAMPLE 15 SILICA 3.43 SQUARE 11.8 93.5 6.5 EXAMPLE 16 SILICA 2.00 SQUARE 4.0 89.7 10.3 EXAMPLE 17 SILICA 2.24 SQUARE 5.0 90.2 9.8 EXAMPLE 18 SILICA 7.09 FAN 39.5 96.9 3.1 EXAMPLE 19 SILICA 7.10 SQUARE 50.0 95.5 4.5 EXAMPLE 20 SILICA 7.41 SQUARE 55.0 95.6 4.4 EXAMPLE 21 SILICA MONOLITHIC 162.0 100.0 0 EXAMPLE 22 ZIRCONIA 3.43 SQUARE 11.8 93.5 6.5 EXAMPLE 23 ZIRCONIA 2.00 SQUARE 4.0 89.7 10.3 EXAMPLE 24 ZIRCONIA 2.24 SQUARE 5.0 90.2 9.8 EXAMPLE 25 ZIRCONIA 7.09 FAN 39.5 96.9 3.1 EXAMPLE 26 ZIRCONIA 7.10 SQUARE 50.0 95.5 4.5 EXAMPLE 27 ZIRCONIA 7.41 SQUARE 55.0 95.6 4.4 EXAMPLE 28 ZIRCONIA MONOLITHIC 162.0 100.0 0 EXAMPLE 29 CORDIERITE + ALUMINA MONOLITHIC 162.0 100.0 0 ¹⁾INORGANIC FIBERS = SILICA-ALUMINA FIBERS (10 μm IN DIAMETER, 100 μm IN LENGTH, ASPECT RATIO OF 10) ²⁾INCLUDING AREA OF COATING MATERIAL LAYER

The contents of Examples 2 through 29 to be described below are also shown together in Table 1. In each sample shown in Table 1, the inorganic fibers are silica-alumina fibers (10 μm in average fiber diameter, 100 μm in average fiber length, and of an aspect ratio of 10), and the inorganic binder is silica sol (of a solid concentration of 30 wt %). Further, Table 2 shows a collection of data such as numerical values on the inorganic fibers (type, diameter, length, and aspect ratio), unit shape, and unit cross-sectional area of each of Examples 30 through 34 to be described below.

TABLE 2 INORGANIC FIBERS UNIT UNIT²⁾ CROSS- DIAMETER LENGTH ASPECT SHAPE SECTIONAL AREA SAMPLE¹⁾ TYPE μm μm RATIO cm cm² EXAMPLE 1 SILICA-ALUMINA FIBERS 10 100 10 3.43 SQUARE 11.8 EXAMPLE 30 SILICA-ALUMINA FIBERS 5 50 10 3.43 SQUARE 11.8 EXAMPLE 31 SILICA-ALUMINA FIBERS 10 20 2 3.43 SQUARE 11.8 EXAMPLE 32 SILICA-ALUMINA FIBERS 10 5000 500 3.43 SQUARE 11.8 EXAMPLE 33 SILICA-ALUMINA FIBERS 10 10000 1000 3.43 SQUARE 11.8 EXAMPLE 34 SILICA-ALUMINA FIBERS 10 20000 2000 3.43 SQUARE 11.8 ¹⁾CERAMIC PARTICLES = γ-ALUMINA PARTICLES ²⁾UNIT AREA RATIO = 93.5% SEAL MATERIAL LAYER + COATING MATERIAL LAYER AREA RATIO = 6.5%

In each sample shown in Table 2, the ceramic particles are γ-alumina particles, the inorganic binder is silica sol (of a solid concentration of 30 wt %), the unit area ratio is 93.5%, and the seal material layer area ratio is 6.5%. Further, Table 3 shows a collection of data such as numerical values on the inorganic binder type, unit cross-sectional area, seal material layer thickness, unit area ratio, seal material layer area ratio, and firing temperature of the honeycomb units 11 of the honeycomb unit 10 of each of Examples 44-51.

TABLE 3 SEAL²⁾ UNIT CROSS- SEAL MATERIAL UNIT AREA MATERIAL LAYER FIRING INORGANIC SECTIONAL AREA LAYER THICKNESS RATIO AREA RATIO TEMPERATURE SAMPLE¹⁾ BINDER TYPE cm² mm % % ° C. EXAMPLE 44 SILICA SOL 11.8 2.0 89.3 10.7 800 EXAMPLE 45 SILICA SOL 11.8 3.0 84.8 15.2 800 EXAMPLE 46 SILICA SOL 5.0 2.0 83.5 16.5 800 EXAMPLE 47 SILICA SOL 5.0 1.5 86.8 13.2 800 EXAMPLE 48 ALUMINA SOL 11.8 1.0 93.5 6.5 800 EXAMPLE 49 SEPIOLITE 11.8 1.0 93.5 6.5 800 EXAMPLE 50 ATTAPULGITE 11.8 1.0 93.5 6.5 800 EXAMPLE 51 — 11.8 1.0 93.5 6.5 1000 ¹⁾CERAMIC PARTICLES = γ-ALUMINA PARTICLES INORGANIC FIBERS = SILICA-ALUMINA FIBERS (10 μm IN DIAMETER, 100 μm IN LENGTH, ASPECT RATIO OF 10) ²⁾INCLUDING AREA OF COATING MATERIAL LAYER

In each sample shown in Table 3, the ceramic particles are γ-alumina particles (2 μm in average particle size), and the inorganic fibers are silica-alumina fibers (10 μm in average fiber diameter, 100 μm in average fiber length, and of an aspect ratio of 10).

Examples 2 through 7

The honeycomb structures 10 were made in the same manner as in Example 1 except that the honeycomb units 11 were made into respective shapes shown in Table 1. The shapes of the joint bodies of Examples 2, 3, and 4 are shown in FIGS. 3B, 3C, and 3D, respectively, and the shapes of the joint bodies of Examples 5, 6, and 7 are shown in FIGS. 4A, 4B, and 4C, respectively. In Example 7, the honeycomb structure 10 was monolithically formed, and accordingly, the joining process and the cutting process were not performed.

Examples 1-A through 1-E

The honeycomb structures 10 in which the thermal conductivity of the seal material layer 14 was varied from 0.05-5.0 W/m·K were made (Examples 1-A through 1-E). The thermal conductivity was controlled using seal material pastes different in the material and/or compounding ratio of ceramic particles, the material and/or compounding ratio of inorganic fibers, and/or the compounding ratio of additives. In Examples 1-A through 1-E, those other than the seal material, such as the composition and the shape of the honeycomb units 11, were prepared in the same manner as in Example 1. Table 4 shows the component mixture ratios used for the seal material pastes of Examples 1-A through 1-E and the thermal conductivities of the seal materials prepared using these seal material pastes.

TABLE 4 CERAMIC PARTICLES INORGANIC FIBERS SiC SiC SILICA-ALUMINA ALUMINA FIBERS SiC FIBERS γ-ALUMINA PARTICLES PARTICLES FIBERS (10 μm (10 μm IN (10 μm IN PARTICLES (2 μm (30 μm IN (0.5 μm IN IN FIBER DIAMETER, FIBER DIAMETER, FIBER DIAMETER, IN PARTICLE PARTICLE PARTICLE 100 μm IN FIBER 100 μm IN 100 μm IN SAMPLE SIZE) SIZE) SIZE) LENGTH) FIBER LENGTH) FIBER LENGTH) EXAMPLE 1 29 — — 7 — — EXAMPLE 1-A 17 — — 3 — — EXAMPLE 1-B 29 — — 7 — — EXAMPLE 1-C 29 — — 7 — — EXAMPLE 1-D — — 29 — 7 — EXAMPLE 1-E — 20 9 — — 7 ADDITIVES SILICA SOL ACRYL (20 μm THERMAL (SOLID CONCENTRATION IN PARTICLE CONDUCTIVITY SAMPLE OF 30%) SIZE) CMC WATER W/mK EXAMPLE 1 34 — 5 25 0.1 EXAMPLE 1-A 30 20 5 25 0.05 EXAMPLE 1-B 34 — 5 25 0.1 EXAMPLE 1-C 34 — 5 25 0.1 EXAMPLE 1-D 34 — 5 25 1.0 EXAMPLE 1-E 34 — 5 25 5.0

The honeycomb structures 10 of these experimental examples were caused to carry 2 g/L of platinum in advance at the honeycomb unit stage in order to be subjected, together with a DPF, to a below-described regeneration test. The honeycomb structures 11 were impregnated with a platinum nitrate solution and heated at 600° C. for 1 hour, so that platinum was carried on the honeycomb structures 10.

Examples 8 through 14

The honeycomb units 11 were made in the same manner as in Example 1 except that the honeycomb units 11 were made into respective shapes shown in Table 1 using titania particles (2 μm in average particle size) instead of ceramic particles. Then, the honeycomb structures 10 were made in the same manner as in Example 1 except that the ceramic particles of the seal material layer 14 and the coating material layer 16 were replaced with titania particles (2 μm in average particle size). The joint bodies of Examples 8 through 11 are equal in shape to those of FIGS. 3A through 3D, respectively. The joint bodies of Examples 12 through 14 are equal in shape to those of FIGS. 4A through 4C, respectively. In Example 14, the honeycomb unit 10 was monolithically formed.

Examples 15 through 21

The honeycomb units 11 were made in the same manner as in Example 1 except that the honeycomb units 11 were made into respective shapes shown in Table 1 using silica particles (2 μm in average particle size) instead of ceramic particles. Then, the honeycomb structures 10 were made in the same manner as in Example 1 except that the ceramic particles of the seal material layer 14 and the coating material layer 16 were replaced with silica particles (2 μm in average particle size). The joint bodies of Examples 15 through 18 are equal in shape to those of FIGS. 3A through 3D, respectively. The joint bodies of Examples 19 through 21 are equal in shape to those of FIGS. 4A through 4C, respectively. In Example 21, the honeycomb unit 10 was monolithically formed.

Examples 22 through 28

The honeycomb units 11 were made in the same manner as in Example 1 except that the honeycomb units 11 were made into respective shapes shown in Table 1 using zirconia particles (2 μm in average particle size) instead of ceramic particles. Then, the honeycomb structures 10 were made in the same manner as in Example 1 except that the ceramic particles of the seal material layer 14 and the coating material layer 16 were replaced with zirconia particles (2 μm in average particle size). The joint bodies of Examples 22 through 25 are equal in shape to those of FIGS. 3A through 3D, respectively. The joint bodies of Examples 26 through 28 are equal in shape to those of FIGS. 4A through 4C, respectively. In Example 28, the honeycomb unit 10 was monolithically formed.

Example 29

A commercially available cylindrical (143. 8 mm in diameter×150 mm in length) cordierite honeycomb structure in which alumina serving as a catalyst carrier layer is formed inside through holes was employed as Example 29. The cell shape was hexagonal, the cell density was 62/cm (400 cpsi), and the wall thickness was 0.18 mm. The shape of the honeycomb structure viewed from its front surface is equal to that of FIG. 4C.

Examples 30 through 34

The honeycomb units 11 were made in the same manner as in Example 1 except that silica-alumina fibers of respective shapes shown in Table 2 were used as inorganic fibers. Then, the honeycomb structures 10 were made in the same manner as in Example 1 except that the same silica-alumina fibers as in the honeycomb units 11 were used for the seal material layer 14 and the coating material layer 16. The joint bodies of Examples 30 through 34 are equal in shape to that of FIG. 3A.

Examples 44 through 47

The honeycomb structures 10 were made in the same manner as in Example 1 except that the cross-sectional areas of the honeycomb units 11 and the thickness of the seal material layer 14 joining the honeycomb units 11 were changed as shown in Table 3. The joint bodies of Examples 44 and 45 are equal in shape to that of FIG. 3A. The joint bodies of Examples 46 and 47 are equal in shape to that of FIG. 3C.

Example 48

The honeycomb structure 10 was made in the same manner as in Example 1 except that alumina sol (of a solid concentration of 30 wt %) was employed as an inorganic binder as shown in Table 3.

Examples 49 and 50

The honeycomb structures 10 were made in the same manner as in Example 1 except that the honeycomb units 11 were made using sepiolite in Example 49 and attapulgite in Example 50 as inorganic binders. Specifically, 40 wt % of γ-alumina particles (2 μm in average particle size), 10 wt % of silica-alumina fibers (10 μm in average fiber diameter, 100 μm in average fiber length, and of an aspect ratio of 10), 15 wt % of an inorganic binder, and 35 wt % of water were mixed, and an organic binder, a plasticizer, and lubricant were added to the obtained mixture as in Example 1. Then, molding and firing were performed, so that the honeycomb units 11 were obtained. Next, the honeycomb units 11 were joined with the same seal material paste as that of Example 1. Then, as in Example 1, the obtained joint body was cut and the coating material layer 16 was formed thereon, so that the cylindrical (143. 8 mm in diameter×150 mm in length) honeycomb structure 10 was obtained.

Example 51

The honeycomb structure 10 was made in the same manner as in Example 1 except that the honeycomb units 11 were made without putting in an inorganic binder. Specifically, 50 wt % of γ-alumina particles (2 μm in average particle size), 15 wt % of silica-alumina fibers (10 μm in average fiber diameter, 100 μm in average fiber length, and of an aspect ratio of 10), and 35 wt % of water were mixed, and as in Example 1, an organic binder, a plasticizer, and lubricant were added to the obtained mixture, and molding was performed. The obtained molded bodies were subjected to firing at 1000° C., so that the honeycomb units 11 were obtained. Next, the honeycomb units 11 were joined with the same seal material paste as that of Example 1. Then, as in Example 1, the obtained joint body was cut and the coating material layer 16 was formed thereon, so that the cylindrical (143. 8 mm in diameter×150 mm in length) honeycomb structure 10 was obtained.

[Specific Surface Area Measurement]

The specific surface areas of the honeycomb units 11 of Examples 1 through 51 and Examples 1-A through 1-E were measured. First, the volumes of the honeycomb units 11 and the seal material were actually measured, and the ratio of the unit material to the volume of the honeycomb structure 10 (=A [vol %]) was calculated. Next, the BET specific surface area per unit weight of the honeycomb units 11 (=B [m²/g]) was measured. The BET specific surface area was measured by the single-point method based on JIS-R-1626 (1996) set by Japanese Industrial Standards using a BET measuring apparatus (Micromeritics FlowSorb II-2300 manufactured by Shimadzu Corporation). In the measurement, a cylindrically cut-out small piece (15 mm in diameter×15 mm in height) was employed as a sample. The apparent density of the honeycomb units 11 (=C [g/L]) was calculated from the weight and the volume of the outer shape of the honeycomb units 11, and the specific surface area of the honeycomb structure 10 (=S [m²/L]) was given by the following Eq. (1). Here, the specific surface area of the honeycomb structure 10 refers to the specific surface area per apparent volume of the honeycomb structure 10. S(m² /L)=(A/100)×B×C.  (1)

The contents of JIS-R-1626 (1996) are incorporated herein by reference in their entirety.

[Repeated Thermal Shock and Vibration Tests]

The honeycomb structures 10 of Examples 1 through 51 and Examples 1-A through 1-E were subjected to repeated thermal shock and vibration tests. In the thermal shock test, each honeycomb structure 10 in a metal casing 21 (FIGS. 5A and 5B) with an alumina mat (MAFTEC, manufactured by Mitsubishi Chemical Functional Products, Inc., 46.5 cm×15 cm, 6 mm in thickness), which is a heat insulator formed of alumina fibers, being around the exterior cylindrical surface of the honeycomb structure 10, was put in a furnace set at 600° C. After being heated for 10 minutes, the honeycomb structure 10 in the metal casing 21 was extracted from the furnace and cooled rapidly to room temperature. Next, the vibration test was conducted on the honeycomb structure 10 in the metal casing 21. FIG. 5A is a front view of a vibration apparatus 20 used for the vibration test. FIG. 5B is a side view of the vibration apparatus 20. The metal casing 21 containing the honeycomb structure 10 was placed on a seat 22, and the metal casing 21 was fixed by fastening substantially U-shaped fixtures 23 with screws 24. As a result, the metal casing 21 was capable of vibrating with the seat 22 and the fixtures 23 as a unit. The vibration test was conducted under the conditions of a frequency of 160 Hz, an acceleration of 30 G, an amplitude of 0.58 mm, a retention time of 10 hours, room temperature, and the vibrating directions along the Z-axis (upward and downward). These thermal shock test and vibration test were repeated alternately ten times each, and the weight of the honeycomb structure 10 before the tests (=T0) and the weight of the honeycomb structure after the tests (=Ti) were measured, so that the rate of weight reduction (=G) was determined using the following Eq. (2). G (wt %)=100×(T0−Ti)/T0.   (2)

[Pressure Loss Measurement]

The pressure loss of each of the honeycomb structures 10 of Examples 1 through 51 and Examples 1-A through 1-E was measured. FIG. 6 is a schematic diagram showing a pressure loss measuring apparatus 40. The measurement was performed as follows. The honeycomb structure 10 having an alumina mat wrapped therearound in a metal casing was placed in the exhaust pipe of a 2L common rail diesel engine 42, and a differential pressure gauge 44 was attached across the honeycomb structure 10. The measurement conditions were an engine speed of 1500 rpm and a torque of 50 Nm, and the differential pressure at 5 minutes after the start of operation was measured.

[Filter Regeneration Test]

The honeycomb structures 10 of Examples 1 through 3, 5, and 6 and Examples 1-A through 1-E and a SiC DPF (diesel particulate filter) were combined into exhaust gas purification test pieces, with which DPF regeneration was evaluated. Each test piece was configured by providing the honeycomb structure 10 (144 mm in diameter×150 mm in length) on the inflow side of the exhaust pipe of an engine, and the DPF, 144 mm in diameter and 150 mm in length, at a position 5 mm away therefrom to the outflow side. First, the engine was operated at a speed of 3000 rpm and a torque of 50 Nm so as to cause the DPF to capture 20 g of soot. Next, in order to burn the soot, the engine operation was switched to post injection, and the engine was operated for 7 minutes. The regeneration rate was determined from the difference in the DPF weight between before and after the burning of the soot (if the soot burns completely, the regeneration rate is 100%).

[Experimental Results]

Table 5 shows a collection of data such as numerical values on the ceramic particle component(s), unit cross-sectional area, unit area ratio, the specific surface area of the honeycomb unit 11, the specific surface area S of the honeycomb structure 10, the thermal conductivity of the seal material layer 14, the weight reduction rate G of the repeated thermal shock and vibration tests, and pressure loss of each of Examples 1 through 29 and 44 through 47. FIG. 7 is a graph showing the cross-sectional area of the honeycomb unit 11 plotted as the horizontal axis, and the weight reduction rate. G of the repeated thermal shock and vibration tests and the pressure loss plotted as the vertical axes. FIG. 8 is a graph showing the unit area ratio plotted as the horizontal axis, and the weight reduction rate G of the repeated thermal shock and vibration tests and the pressure loss plotted as the vertical axes.

TABLE 5 SEAL UNIT MATERIAL REDUCTION CROSS- UNIT STRUCTURE LAYER RATE G OF SEC- UNIT SPECIFIC SPECIFIC THERMAL THERMAL PRES- CERAMIC TIONAL AREA SURFACE SURFACE CONDUC- SHOCK AND SURE REGEN. PARTI- AREA RATIO AREA AREAS TIVITY VIBRATION LOSS RATE SAMPLE^(※) CLES cm² % m²/L m²/L W/mK TESTS wt % kPa % EXAMPLE 1 ALUMINA 11.8 93.5 42000 39270 0.1 0 2.4 85 EXAMPLE 2 ALUMINA 4.0 89.7 42000 37674 0.1 0 2.8 75 EXAMPLE 3 ALUMINA 5.0 90.2 42000 37884 0.1 0 2.5 80 EXAMPLE 4 ALUMINA 39.5 96.9 42000 40698 — 5 2.2 — EXAMPLE 5 ALUMINA 50.0 95.5 42000 40110 0.1 3 2.3 87 EXAMPLE 6 ALUMINA 55.0 95.6 42000 40152 0.1 52 2.3 87 EXAMPLE 7 ALUMINA 162.0 100.0 42000 42000 — 70 2.1 — EXAMPLE 1-A TITANIA 11.8 93.5 42000 39270 0.05 7 2.4 53 EXAMPLE 1-B TITANIA 11.8 96.5 42000 40530 0.1 5 2.3 87 EXAMPLE 1-C TITANIA 11.8 89.3 42000 37506 0.1 0 2.5 82 EXAMPLE 1-D TITANIA 11.8 93.5 42000 39270 1.0 0 2.4 90 EXAMPLE 1-E TITANIA 11.8 93.5 42000 39270 5.0 0 2.4 92 EXAMPLE 8 TITANIA 11.8 93.5 38000 35530 — 0 2.4 — EXAMPLE 9 TITANIA 4.0 89.7 38000 34086 — 0 2.8 — EXAMPLE 10 TITANIA 5.0 90.2 38000 34276 — 0 2.5 — EXAMPLE 11 TITANIA 39.5 96.9 38000 36822 — 7 2.2 — EXAMPLE 12 TITANIA 50.0 95.5 38000 36290 — 5 2.3 — EXAMPLE 13 TITANIA 55.0 95.6 38000 36328 — 63 2.3 — EXAMPLE 14 TITANIA 162.0 100.0 38000 38000 — 90 2.1 — EXAMPLE 15 SILICA 11.8 93.5 41000 38335 — 0 2.4 — EXAMPLE 16 SILICA 4.0 89.7 41000 36777 — 0 2.8 — EXAMPLE 17 SILICA 5.0 90.2 41000 36982 — 0 2.5 — EXAMPLE 18 SILICA 39.5 96.9 41000 39729 — 4 2.2 — EXAMPLE 19 SILICA 50.0 95.5 41000 39155 — 3 2.3 — EXAMPLE 20 SILICA 55.0 95.6 41000 39196 — 42 2.3 — EXAMPLE 21 SILICA 162.0 100.0 41000 41000 — 65 2.1 — EXAMPLE 22 ZIRCONIA 11.8 93.5 41500 38803 — 0 2.4 — EXAMPLE 23 ZIRCONIA 4.0 89.7 41500 37226 — 0 2.8 — EXAMPLE 24 ZIRCONIA 5.0 90.2 41500 37433 — 0 2.5 — EXAMPLE 25 ZIRCONIA 39.5 96.9 41500 40214 — 5 2.2 — EXAMPLE 26 ZIRCONIA 50.0 95.5 41500 39633 — 3 2.3 — EXAMPLE 27 ZIRCONIA 55.0 95.6 41500 39674 — 57 2.3 — EXAMPLE 28 ZIRCONIA 162.0 100.0 41500 41500 — 83 2.1 — EXAMPLE 29 CORDIERITE + 162.0 100.0 25000 25000 — 0 2.9 — ALUMINA EXAMPLE 44 ALUMINA 11.8 89.3 42000 37506 — 0 3.1 — EXAMPLE 45 ALUMINA 11.8 84.8 42000 35616 — 0 4.3 — EXAMPLE 46 ALUMINA 5.0 83.5 42000 35070 — 0 4.4 — EXAMPLE 47 ALUMINA 5.0 86.8 42000 36456 — 0 3.3 — ^(※)INORGANIC FIBERS = SILICA-ALUMINA FIBERS (10 μm IN DIAMETER, 100 μm IN LENGTH, ASPECT RATIO OF 10)

The measurement results of Examples 1 through 29 and 44 through 47 shown in Table 5 and FIG. 7 clearly show that with ceramic particles, inorganic fibers, and an inorganic binder being employed as principal components and the cross-sectional area of the honeycomb unit 11 being within 5-50 cm², the honeycomb structure 10 has a large specific surface area per unit volume and sufficient strength against thermal shock and vibration. Further, it has also been found that as shown in FIG. 8, with ceramic particles, inorganic fibers, and an inorganic binder being employed as principal components, the cross-sectional area of the honeycomb unit 11 being less than or equal to 50 cm², and the unit area ratio being greater than or equal to 85%, the honeycomb structure 10 has a large specific surface area per unit volume, sufficient strength against thermal shock and vibration, and reduced pressure loss. In particular, when the unit area ratio is greater than or equal to 90%, the pressure loss decreases conspicuously.

The results of the regeneration test are shown in Table 5. These results show that the filter regeneration rate (regen. rate) is high when the unit cross-sectional area is greater than or equal to 5 cm² and less than or equal to 50 cm² and the thermal conductivity of the seal material layer 14 falls within the range of 0.1 W/m·K to 5 W/m·K.

Next, Table 6 shows a collection of numerical data on the diameter, length, and aspect ratio of the silica-alumina fibers; the specific surface area of the honeycomb unit 11; the specific surface area S of the honeycomb structure 10; the weight reduction rate G of the repeated thermal shock and vibration tests; and the pressure loss of Examples 1 and 30 through 34 in which the aspect ratio of inorganic fibers was varied. FIG. 9 is a graph showing the aspect ratio of the silica-alumina fibers plotted as the horizontal axis, and the weight reduction rate G of the repeated thermal shock and vibration tests plotted as the vertical axis with respect to Examples 1 and 30 through 34.

TABLE 6 REDUCTION RATE G OF THERMAL SILICA-ALUMINA FIBERS UNIT SPECIFIC STRUCTURE SPECIFIC SHOCK AND PRESSURE DIAMETER LENGTH ASPECT SURFACE AREA SURFACE AREAS VIBRATION TESTS LOSS SAMPLE^(※) μm μm RATIO m²/L m²/L wt % kPa EXAMPLE 1 10 100 10 42000 39270 0 2.4 EXAMPLE 30 5 50 10 42000 39270 2 2.4 EXAMPLE 31 10 20 2 42000 39270 8 2.4 EXAMPLE 32 10 5000 500 42000 39270 4 2.4 EXAMPLE 33 10 10000 1000 42000 39270 6 2.4 EXAMPLE 34 10 20000 2000 42000 39270 25 2.4 ^(※)CERAMIC PARTICLES = γ-ALUMINA PARTICLES

These results show that sufficient strength against thermal shock and vibration can be obtained when the aspect ratio of inorganic fibers falls within the range of 2-1000.

Next, Table 7 shows a collection of data such as numerical values on the inorganic binder type, the firing temperature of the honeycomb unit 11, unit area ratio, the specific surface area of the honeycomb unit 11, the specific surface area S of the honeycomb structure 10, the weight reduction rate G of the repeated thermal shock and vibration tests, and pressure loss of each of Examples 48 through 50, in which the honeycomb units 11 were made with different types of inorganic binders, and Example 51, in which the honeycomb units 11 were made without putting in an inorganic binder.

TABLE 7 STRUCTURE REDUCTION RATE SPECIFIC G OF THERMAL INORGANIC UNIT AREA FIRING UNIT SPECIFIC SURFACE SHOCK AND PRESSURE BINDER RATIO TEMPERATURE SURFACE AREA AREAS VIBRATION TESTS LOSS SAMPLE^(※) TYPE % ° C. m²/L m²/L wt % kPa EXAMPLE 48 ALUMINA SOL 93.5 800 42000 39270 0 2.4 EXAMPLE 49 SEPIOLITE 93.5 800 42000 39270 0 2.4 EXAMPLE 50 ATTAPULGITE 93.5 800 42000 39270 0 2.4 EXAMPLE 51 — 93.5 1000 42000 37400 20 2.4 ^(※)CERAMIC PARTICLES = γ-ALUMINA PARTICLES INORGANIC FIBERS = SILICA-ALUMINA FIBERS (10 μm IN DIAMETER, 100 μm IN LENGTH, ASPECT RATIO OF 10) UNIT SHAPE = 3.43 cm square

These results show that when no inorganic binder is put in, sufficient strength can be obtained by firing at relatively high temperatures. Further, these results show that sufficient strength can also be obtained by firing at relatively low temperatures when an inorganic binder is put in. These results also show that even when the inorganic binder is alumina sol or a clay-based binder, the honeycomb structure 10 can have a great specific surface area per unit volume and sufficient strength against thermal shock and vibration.

According to one embodiment of the present invention, in a honeycomb structure having multiple honeycomb units united through a seal material layer, the honeycomb units each having multiple through holes arranged side by side in a longitudinal direction and separated from each other by the wall surfaces of the through holes, the honeycomb units include at least ceramic particles and inorganic fibers and/or whiskers, at least one of the honeycomb units has a cross section perpendicular to a longitudinal direction thereof, the cross section having an area greater than or equal to about 5 cm² and less than or equal to about 50 cm², and the seal material layer has a thermal conductivity of about 0.1 W/m·K to about 5 W/m·K.

Thus, a honeycomb structure that is capable of achieving high dispersion of a catalyst component and increasing strength against thermal shock and vibration, loses less heat, and has excellent thermal uniformity can be provided.

Additionally, in the honeycomb structure, the ratio of the total of the areas of the cross sections of the honeycomb units perpendicular to the longitudinal direction thereof to the area of a cross section of the honeycomb structure perpendicular to a longitudinal direction thereof is greater than or equal to about 85%. This makes it possible to cause a relative increase in the surface area capable of carrying a catalyst, and a relative reduction in pressure loss.

Additionally, the honeycomb structure may include a coating material layer on the exterior axial surface of the joint body of the honeycomb units. This makes it possible to increase the strength of the honeycomb structure by protecting its exterior surface.

Additionally, in the honeycomb structure, the ceramic particles may include at least one selected from alumina, silica, zirconia, titania, ceria, mullite, and zeolite. This makes it possible to increase the specific surface area of the honeycomb units.

Additionally, in the honeycomb structure the inorganic fibers and/or the whiskers may include at least one selected from alumina, silica, silicon carbide, silica alumina, glass, potassium titanate, and aluminum borate. This makes it possible to increase the strength of the honeycomb units.

Additionally, in the honeycomb structure, the honeycomb units may be manufactured using a mixture including the ceramic particles, the inorganic fibers and/or the whiskers, and an inorganic binder; and the inorganic binder may include at least one selected from alumina sol, silica sol, titania sol, water glass, sepiolite, and attapulgite. This makes it possible to obtain sufficient strength even if the honeycomb units are subjected to firing at low temperatures.

Additionally, a catalyst component may be carried on the honeycomb structure. As a result, a honeycomb catalyst having a catalyst component highly dispersed can be obtained.

Additionally, in the honeycomb structure, the catalyst component may include at least one component selected from noble metal, alkali metal, alkaline earth metal, and oxide. This makes it possible to increase conversion performance.

Additionally, the honeycomb structure may be used for converting the exhaust gas of a vehicle.

The present invention may be applied to a catalyst carrier for converting (purifying) the exhaust gas of vehicles and an adsorbent adsorbing a gas component or a liquid component.

The present invention is not limited to the specifically disclosed embodiment, and variations and modifications may be made without departing from the scope of the present invention.

The present application is based on PCT International Application No. PCT/JP2005/011656, filed on Jun. 24, 2005, the entire contents of which are hereby incorporated by reference. 

1. A honeycomb structure having a plurality of honeycomb units united through a seal material layer, the honeycomb units each having a plurality of through holes arranged side by side in a longitudinal direction and separated from each other by wall surfaces of the through holes, all of the through holes being open on an end face of the honeycomb unit, wherein: the honeycomb units comprise at least: ceramic particles and at least one of inorganic fibers and whiskers, thereby increasing a specific surface area of the honeycomb units; at least one of the honeycomb units has a cross section perpendicular to a longitudinal direction thereof, the cross section having an area greater than or equal to about 5 cm² and less than or equal to about 50 cm²; a ratio of a total cross sectional area of all the honeycomb units, perpendicular to the longitudinal direction thereof, to an area of a cross section of the honeycomb structure, perpendicular to a longitudinal direction thereof, is greater than or equal to about 85%; the ceramic particles comprise at least one selected from the group consisting of alumina, silica, zirconia, titania, ceria, mullite, and zeolite; the honeycomb units are formed by firing a material including the ceramic particles at the at least one of the inorganic fibers and the whiskers at about 600° C. to about 1200° C.; and the seal material layer has a thermal conductivity of about 0.1 W/mK to about 5 W/m K.
 2. The honeycomb structure as claimed in claim 1, further comprising: a coating material layer on an exterior axial surface of a joint body into which the honeycomb units are united.
 3. The honeycomb structure as claimed in claim 1, wherein the at least one of the inorganic fibers and the whiskers comprise at least one selected from the group consisting of alumina, silica, silicon carbide, silica alumina, glass, potassium titanate, and aluminum borate.
 4. The honeycomb structure as claimed in claim 1, wherein: the honeycomb units are manufactured using a mixture including the ceramic particles, the at least one of the inorganic fibers and the whiskers, and an inorganic binder; and the inorganic binder comprises at least one selected from the group consisting of alumina sol, silica sol, titania sol, water glass, sepiolite, and attapulgite.
 5. The honeycomb structure as claimed in claim 1, wherein a catalyst component is carried on the honeycomb structure.
 6. The honeycomb structure as claimed in claim 5, wherein the catalyst component comprises at least one component selected from the group of noble metal, alkali metal, alkaline earth metal, and oxide.
 7. The honeycomb structure as claimed in claim 1, wherein the honeycomb structure is used for conversion of exhaust gas of a vehicle.
 8. The honeycomb structure as claimed in claim 1, wherein a number of the through holes per unit cross-sectional area is about 15.5/cm² to about 186/cm².
 9. The honeycomb structure as claimed in claim 1, wherein the seal material layer is about 0.3 mm to about 2 mm in thickness.
 10. The honeycomb structure as claimed in claim 1, wherein a wall between the through holes is about 0.05 mm to about 0.35 mm in thickness.
 11. The honeycomb structure as claimed in claim 1, wherein an amount of the at least one of the inorganic fibers and the whiskers included in the honeycomb structure is about 3 wt % to about 70 wt %.
 12. The honeycomb structure as claimed in claim 1, wherein the inorganic fibers are silica-alumina fibers. 